Characterization of [11C]Methyl-Losartan as a Novel Radiotracer for PET Imaging of the AT1 Receptor

Antoun, Rawad

09 March 2011

The Angiotensin II Type 1 (AT1) receptor is the main receptor responsible for the effects of the renin-angiotensin system, and its expression pattern is altered in several diseases. [11C]Methyl-Losartan has been developed based on the clinically used AT1 receptor antagonist Losartan. The aim of this work is to characterize the pharmacokinetics, repeatability and reliability of measurements, binding specificity and selectivity of [11C]Methyl-Losartan in rats using in vivo small animal positron emission tomography (PET) imaging, ex vivo biodistribution and in vitro autoradiography methods. Also, we aim to measure the presence of metabolites in the kidney and plasma using high-performance liquid chromatography. We have demonstrated in vivo that [11C]Methyl-Losartan is taken up in the AT1 receptor-rich kidneys and that it is displaceable by selective AT1 receptor antagonists. Using ex vivo biodistribution, we have confirmed these results and demonstrated that [11C]Methyl-Losartan binds selectively to the AT1 receptor over the AT2, Mas and β-adrenergic receptors. In vitro autoradiography results confirmed these renal binding selectivity studies. [11C]Methyl-Losartan was also shown to have one and two C-11 labeled metabolites in the plasma and kidneys, respectively. In conclusion, [11C]Methyl-Losartan is a promising agent for studying the AT1 receptor in rat models with normal and altered AT1 receptor expression using small animal PET imaging.

Renin-angiotensin System

Losartan

[11C]Methyl-Losartan

Renal PET Imaging

Angiotensin II Type 1 (AT1) Receptor

Modulation of arterial stiffness by angiotensin receptors and nitric oxide in the insulin resistance syndrome

Brillante, Divina Graciela, Clinical School - St George Hospital, Faculty of Medicine, UNSW

January 2008

The insulin resistance syndrome [INSR] is associated with increased cardiovascular risk and affects up to 25% of the Australian population. The mechanism underlying the relationship between the INSR and increased cardiovascular risk is controversial. We postulated that perturbations in the renin-angiotensin system [RAS] and endothelium-derived NO may be implicated in the development of early vascular changes in the INSR. Repeated measurements of arterial stiffness [using digital photoplethysmography] and haemodynamic parameters in response to vasoactive medications were used to demonstrate the functional expression of angiotensin II [Ang II] receptors and NO synthase [NOS]. Ang II acts via two main receptor sub-types: the Ang II type 1 [AT1] and Ang II type 2 [AT2] receptors. The AT1 receptor is central to the development of arterial stiffness and endothelial dysfunction. The role of AT2 receptors in humans is controversial but is postulated to counter-act AT1 receptor mediated effects in diseased vascular beds. We demonstrated increased AT1 and AT2 receptor-mediated effects in small to medium-sized arteries of subjects with early INSR [Chapter 6]. In addition, functional expression of AT2 receptors in adult insulin resistant humans [Chapter 5], but not in healthy volunteers [Chapter 4] was demonstrated. AT1 receptor blockade in subjects with early INSR resulted in improvements in vascular function, with a consequent functional down-regulation of AT2 receptors [Chapter 7]. Functional NOS expression was demonstrated to be increased in subjects with early INSR compared with healthy controls [Chapter 6]. This was postulated to be a homeostatic response to counteract early vascular changes in subjects with early INSR. AT1 receptor blockade in these subjects reduced functional NOS expression [Chapter 8]. In conclusion, patients with early INSR represent a model of early disease where early intervention may be able to reverse the process incited by the initial exposure to multiple cardiovascular risk factors. Early vascular changes in these individuals are mediated at least in part, by increased AT1 receptor activity and/or expression, and may be detected by changes in arterial stiffness indices and non-invasive vascular reactivity studies. There is a compensatory increase in AT2 receptor and NOS expression/activity to counter-act these vascular changes.

Arterial stiffness.

Insulin resistance syndrome.

Metabolic syndrome.

Nitric oxide.

Angiotensin receptors.

AT1 receptor.

AT2 receptor.

Modulation of arterial stiffness by angiotensin receptors and nitric oxide in the insulin resistance syndrome

Brillante, Divina Graciela, Clinical School - St George Hospital, Faculty of Medicine, UNSW

January 2008

The insulin resistance syndrome [INSR] is associated with increased cardiovascular risk and affects up to 25% of the Australian population. The mechanism underlying the relationship between the INSR and increased cardiovascular risk is controversial. We postulated that perturbations in the renin-angiotensin system [RAS] and endothelium-derived NO may be implicated in the development of early vascular changes in the INSR. Repeated measurements of arterial stiffness [using digital photoplethysmography] and haemodynamic parameters in response to vasoactive medications were used to demonstrate the functional expression of angiotensin II [Ang II] receptors and NO synthase [NOS]. Ang II acts via two main receptor sub-types: the Ang II type 1 [AT1] and Ang II type 2 [AT2] receptors. The AT1 receptor is central to the development of arterial stiffness and endothelial dysfunction. The role of AT2 receptors in humans is controversial but is postulated to counter-act AT1 receptor mediated effects in diseased vascular beds. We demonstrated increased AT1 and AT2 receptor-mediated effects in small to medium-sized arteries of subjects with early INSR [Chapter 6]. In addition, functional expression of AT2 receptors in adult insulin resistant humans [Chapter 5], but not in healthy volunteers [Chapter 4] was demonstrated. AT1 receptor blockade in subjects with early INSR resulted in improvements in vascular function, with a consequent functional down-regulation of AT2 receptors [Chapter 7]. Functional NOS expression was demonstrated to be increased in subjects with early INSR compared with healthy controls [Chapter 6]. This was postulated to be a homeostatic response to counteract early vascular changes in subjects with early INSR. AT1 receptor blockade in these subjects reduced functional NOS expression [Chapter 8]. In conclusion, patients with early INSR represent a model of early disease where early intervention may be able to reverse the process incited by the initial exposure to multiple cardiovascular risk factors. Early vascular changes in these individuals are mediated at least in part, by increased AT1 receptor activity and/or expression, and may be detected by changes in arterial stiffness indices and non-invasive vascular reactivity studies. There is a compensatory increase in AT2 receptor and NOS expression/activity to counter-act these vascular changes.

Arterial stiffness.

Insulin resistance syndrome.

Metabolic syndrome.

Nitric oxide.

Angiotensin receptors.

AT1 receptor.

AT2 receptor.

Modulation of arterial stiffness by angiotensin receptors and nitric oxide in the insulin resistance syndrome

Brillante, Divina Graciela, Clinical School - St George Hospital, Faculty of Medicine, UNSW

January 2008

The insulin resistance syndrome [INSR] is associated with increased cardiovascular risk and affects up to 25% of the Australian population. The mechanism underlying the relationship between the INSR and increased cardiovascular risk is controversial. We postulated that perturbations in the renin-angiotensin system [RAS] and endothelium-derived NO may be implicated in the development of early vascular changes in the INSR. Repeated measurements of arterial stiffness [using digital photoplethysmography] and haemodynamic parameters in response to vasoactive medications were used to demonstrate the functional expression of angiotensin II [Ang II] receptors and NO synthase [NOS]. Ang II acts via two main receptor sub-types: the Ang II type 1 [AT1] and Ang II type 2 [AT2] receptors. The AT1 receptor is central to the development of arterial stiffness and endothelial dysfunction. The role of AT2 receptors in humans is controversial but is postulated to counter-act AT1 receptor mediated effects in diseased vascular beds. We demonstrated increased AT1 and AT2 receptor-mediated effects in small to medium-sized arteries of subjects with early INSR [Chapter 6]. In addition, functional expression of AT2 receptors in adult insulin resistant humans [Chapter 5], but not in healthy volunteers [Chapter 4] was demonstrated. AT1 receptor blockade in subjects with early INSR resulted in improvements in vascular function, with a consequent functional down-regulation of AT2 receptors [Chapter 7]. Functional NOS expression was demonstrated to be increased in subjects with early INSR compared with healthy controls [Chapter 6]. This was postulated to be a homeostatic response to counteract early vascular changes in subjects with early INSR. AT1 receptor blockade in these subjects reduced functional NOS expression [Chapter 8]. In conclusion, patients with early INSR represent a model of early disease where early intervention may be able to reverse the process incited by the initial exposure to multiple cardiovascular risk factors. Early vascular changes in these individuals are mediated at least in part, by increased AT1 receptor activity and/or expression, and may be detected by changes in arterial stiffness indices and non-invasive vascular reactivity studies. There is a compensatory increase in AT2 receptor and NOS expression/activity to counter-act these vascular changes.

Arterial stiffness.

Insulin resistance syndrome.

Metabolic syndrome.

Nitric oxide.

Angiotensin receptors.

AT1 receptor.

AT2 receptor.

Characterization of [11C]Methyl-Losartan as a Novel Radiotracer for PET Imaging of the AT1 Receptor

Antoun, Rawad

January 2011

The Angiotensin II Type 1 (AT1) receptor is the main receptor responsible for the effects of the renin-angiotensin system, and its expression pattern is altered in several diseases. [11C]Methyl-Losartan has been developed based on the clinically used AT1 receptor antagonist Losartan. The aim of this work is to characterize the pharmacokinetics, repeatability and reliability of measurements, binding specificity and selectivity of [11C]Methyl-Losartan in rats using in vivo small animal positron emission tomography (PET) imaging, ex vivo biodistribution and in vitro autoradiography methods. Also, we aim to measure the presence of metabolites in the kidney and plasma using high-performance liquid chromatography. We have demonstrated in vivo that [11C]Methyl-Losartan is taken up in the AT1 receptor-rich kidneys and that it is displaceable by selective AT1 receptor antagonists. Using ex vivo biodistribution, we have confirmed these results and demonstrated that [11C]Methyl-Losartan binds selectively to the AT1 receptor over the AT2, Mas and β-adrenergic receptors. In vitro autoradiography results confirmed these renal binding selectivity studies. [11C]Methyl-Losartan was also shown to have one and two C-11 labeled metabolites in the plasma and kidneys, respectively. In conclusion, [11C]Methyl-Losartan is a promising agent for studying the AT1 receptor in rat models with normal and altered AT1 receptor expression using small animal PET imaging.

Renin-angiotensin System

Losartan

[11C]Methyl-Losartan

Renal PET Imaging

Angiotensin II Type 1 (AT1) Receptor

Part 1: An Investigation Of Protein: Protein Interactions Related To Hypertension And Pertussis; Part 2: The Use Of Municipal Wastewater As A Medium For Cultivation And Induction Of Lipid Synthesis In The Oleaginous Yeast Rhodotorula Glutinis

Hetrick, Mary Michelle

10 December 2010

The Renin Angiotensin System (RAS) plays a vital role in the regulation of blood pressure and fluid homeostasis. RAS is regulated via the hormone Angiotensin II through an association with the Na+/H+ exchanger NHE6. Here, NHE6 was found to be activated by Angiotensin II through the Angiotensin II AT1 receptor. Furthermore, it was shown that NHE6 requires phosphorylation for activation and this phosphorylation signaling mechanism does not involve phospholipase C. The elucidation of the signaling pathway associated with NHE6 and AT1 allows for the greater understanding of function and regulation of the NHE6 protein. The Angiotensin receptor AT2 is a G-coupled protein receptor (GPCR) that is highly expressed in infant neural tissue. The S1 subunit of the pertussis toxin can inhibit GPCR signaling via ADP-ribosylation of the cognate Gi protein, suggesting that the S1 subunit may interfere with AT2 signaling. In order to observe whether S1 associates with AT2, Chinese hamster ovary cells were transfected with plasmids expressing AT2 or mutants of AT2. The lysates of these cells were incubated with His-tagged S1 subunit and it was observed that only the wild-type AT2 co-immunoprecipitated with S1. These results imply that there is a direct interaction between the S1 subunit and AT2. Municipal wastewater can be considered as an effective growth medium for the cultivation of microorganisms due to organic material found in the water. Oleaginous microorganisms produce large amounts of triacylglycerols (TAGs) when cultivated on medium containing high sugar content and low nitrogen. These TAGs can then be converted into biodiesel. To determine if the oleaginous yeast Rhodotorula glutinis could survive and synthesize lipids using wastewater as a cultivation medium, R. glutinis was inoculated into primary effluent wastewater supplemented with glucose. Results indicated that R. glutinis was able to survive and synthesize lipids in the wastewater which is suggestive that R. glutinis can successfully compete with indigenous microorganisms in the wastewater.

Rhodotorula glutinis

Oleaginous Microorganisms

Pertussis Toxin

NHE6

Angiotensin II

AT2

AT1

Bedeutung der Blockade des lokalen Angiotensinsystems für die chronisch progrediente Niereninsuffizienz im Rahmen der Alport-Nephritis / Significance of Blockade of the Local Angiotensin System for Chronic Progressive Renal Insufficiency in context of alport nephritis

Bemme, Sebastian

03 September 2012

No description available.

610 Medizin, Gesundheit

MED 417 Nephrologie

Medicine

Niereninsuffizienz

Alport-Syndrom

Angiotensin

Fibrosierung

ACE-Hemmer

Enalapril

AT1-Rezeptor-Antagonist

Irbesartan

renal insufficiency

alport syndrome

angiotensin

fibrosis

ACE inhibitor

enalapril

AT1 receptor antagonist

44.61 Innere Medizin

44.88 Urologie

Nephrologie

Design and Synthesis of AT₂ Receptor Selective Angiotensin II Analogues Encompassing <i>β</i>- and <i>γ</i>-Turn Mimetics

Rosenström, Ulrika

January 2004

<p>Important information on the bioactive conformation of biologically active peptides may be obtained by studies of rigid peptides or well-defined secondary structure mimetics incorporated into pseudopeptides. The structural requirements for the interaction of angiotensin II (Ang II, Asp-Arg-Val-Tyr-Ile-His-Pro-Phe) with its AT₁ and AT₂ receptors were the subject of this study.</p><p>The main objectives of this work were to synthesize secondary structure mimetics and incorporate these into Ang II. Ang II has been suggested to adopt a turn conformation around Tyr⁴ when interacting with its AT₁ receptor. Therefore, two <i>γ</i>- and one <i>β</i>-turn mimetic scaffolds based on the benzodiazepine structure were synthesized and decorated with side chains. The scaffolds replaced the turn region around Tyr⁴. Most of the pseudopeptides obtained after incorporation into Ang II exhibited high AT₂/AT₁ selectivity and nanomolar affinity to the AT₂ receptor. One pseudopeptide encompassing a <i>β</i>-turn mimetic also displayed AT₁ receptor affinity.</p><p>We hypothesized that the position of the guanidino group of the arginine residue and the N-terminal end, in relation to the tyrosine side chain, was critical for AT₂ receptor affinity. Conformational evaluation of the pseudopeptides revealed that in all the compounds with AT₂ receptor affinity the arginine side chain and the N-terminal end could reach common regions, not accessible to the inactive compound. It is proposed that Ang II has a more extended bioactive conformation when binding to the AT₂ receptor than when binding to the AT₁ receptor.</p><p>Furthermore, in a Gly scan of Ang II only replacement of the arginine residue reduced the affinity for the AT₂ receptor considerably. Some N-terminal modified Ang II analogues were also synthesized and it was concluded that truncated Ang II analogues interact with the AT₂ receptor differently than Ang II.</p><p>Three of the synthesized pseudopeptides were evaluated in AT₂ receptor functional assays and were found to act as agonists.</p>

Pharmaceutical chemistry

Angiotensin II

AT2

AT1

Benzodiazepine

Peptidomimetics

γ-turn

β-turn

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

Computational Modeling of the AT₂ Receptor and AT₂ Receptor Ligands : Investigating Ligand Binding, Structure–Activity Relationships, and Receptor-Bound Models

Sköld, Christian

January 2007

<p>Rational conversion of biologically active peptides to nonpeptide compounds with retained activity is an appealing approach in drug development. One important objective of the work presented in this thesis was to use computational modeling to aid in such a conversion of the peptide angiotensin II (Ang II, Asp-Arg-Val-Tyr-Ile-His-Pro-Phe). An equally important objective was to gain an understanding of the requirements for ligand binding to the Ang II receptors, with a focus on interactions with the AT₂ receptor.</p><p>The bioactive conformation of a peptide can provide important guidance in peptidomimetic design. By designing and introducing well-defined secondary structure mimetics into Ang II the bioactive conformation can be addressed. In this work, both γ- and β-turn mimetic scaffolds have been designed and characterized for incorporation into Ang II. Using conformational analysis and the pharmacophore recognition method DISCO, a model was derived of the binding mode of the pseudopeptide Ang II analogues. This model indicated that the positioning of the Arg side chain was important for AT₂ receptor binding, which was also supported when the structure–activity relationship of Ang II was investigated by performing a glycine scan.</p><p>To further examine ligand binding, a 3D model of the AT₂ receptor was constructed employing homology modeling. Using this receptor model in a docking study of the ligands, binding modes were identified that were in agreement with data from point-mutation studies of the AT₂ receptor.</p><p>By investigating truncated Ang II analogues, small pseudopeptides were developed that were structurally similar to nonpeptide AT₂ receptor ligands. For further guidance in ligand design of nonpeptide compounds, three-dimensional quantitative structure–activity relationship models for AT₁ and AT₂ receptor affinity as well as selectivity were derived. </p>

Pharmaceutical chemistry

Angiotensin II

AT1

AT2

SAR

bioactive conformation

turn mimetic

peptidomimetic

DISCO

homology model

3D-QSAR

CoMFA

Farmaceutisk kemi

Design and Synthesis of AT2 Receptor Selective Angiotensin II Analogues Encompassing β- and γ-Turn Mimetics

Rosenström, Ulrika

January 2004

Important information on the bioactive conformation of biologically active peptides may be obtained by studies of rigid peptides or well-defined secondary structure mimetics incorporated into pseudopeptides. The structural requirements for the interaction of angiotensin II (Ang II, Asp-Arg-Val-Tyr-Ile-His-Pro-Phe) with its AT1 and AT2 receptors were the subject of this study. The main objectives of this work were to synthesize secondary structure mimetics and incorporate these into Ang II. Ang II has been suggested to adopt a turn conformation around Tyr4 when interacting with its AT1 receptor. Therefore, two γ- and one β-turn mimetic scaffolds based on the benzodiazepine structure were synthesized and decorated with side chains. The scaffolds replaced the turn region around Tyr4. Most of the pseudopeptides obtained after incorporation into Ang II exhibited high AT2/AT1 selectivity and nanomolar affinity to the AT2 receptor. One pseudopeptide encompassing a β-turn mimetic also displayed AT1 receptor affinity. We hypothesized that the position of the guanidino group of the arginine residue and the N-terminal end, in relation to the tyrosine side chain, was critical for AT2 receptor affinity. Conformational evaluation of the pseudopeptides revealed that in all the compounds with AT2 receptor affinity the arginine side chain and the N-terminal end could reach common regions, not accessible to the inactive compound. It is proposed that Ang II has a more extended bioactive conformation when binding to the AT2 receptor than when binding to the AT1 receptor. Furthermore, in a Gly scan of Ang II only replacement of the arginine residue reduced the affinity for the AT2 receptor considerably. Some N-terminal modified Ang II analogues were also synthesized and it was concluded that truncated Ang II analogues interact with the AT2 receptor differently than Ang II. Three of the synthesized pseudopeptides were evaluated in AT2 receptor functional assays and were found to act as agonists.

Pharmaceutical chemistry

Angiotensin II

AT2

AT1

Benzodiazepine

Peptidomimetics

γ-turn

β-turn

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi